Diamondlike Carbon Materials as Low-k Dielectrics for Multilevel Interconnects in Ulsi

Grill, A.; Patel, V.; Saenger, K. L.; Jahnes, C.; Cohen, S.; Schrott, A. G.; Edelstein, Dan; Paraszczak, J.

doi:10.1557/proc-443-155

Cited by 42 publications

(41 citation statements)

References 7 publications

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“…There are some experimental techniques for characterization of DLC, for example, Fourier transform infrared spectroscopy (FTIR), high resolution nuclear magnetic resolution (NMR), electron energy loss spectroscopy (EELS), X-Ray Photoelectron Spectroscopy (XPS), Auger spectroscopy, etc. It also has been reported that by either thermal activation 17,18 or low energetic ion irradiations, 19 the structure of the metastable DLC materials will convert some sp 3 bonds to sp 2 bonds towards graphite-like carbon. 11 Thus a fundamental understanding of carbon hybridization under low energetic carbon atom bombardments is of great interest.…”

Section: Introductionmentioning

confidence: 99%

Conditions for forming composite carbon nanotube-diamond like carbon material that retain the good properties of both materials

Ren

Iyer

Koskinen

et al. 2015

Journal of Applied Physics

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Gold nanoparticle formation in diamond-like carbon using two different methods: Gold ion implantation and codeposition of gold and carbon J. Appl. Phys. 112, 074312 (2012) Carbon nanotubes are of wide interest due to their excellent properties such as tensile strength and electrical and thermal conductivity, but are not, when placed alone on a substrate, well resistant to mechanical wear. Diamond-like carbon (DLC), on the other hand, is widely used in applications due to its very good wear resistance. Combining the two materials could provide a very durable pure carbon nanomaterial enabling to benefit from the best properties of both carbon allotropes. However, the synthesis of high-quality diamond-like carbon uses energetic plasmas, which can damage the nanotubes. From previous works it is neither clear whether the quality of the tubes remains good after DLC deposition, nor whether the DLC above the tubes retains the high sp 3 bonding fraction. In this work, we use experiments and classical molecular dynamics simulations to study the mechanisms of DLC formation on various carbon nanotube compositions. The results show that high-sp 3 -content DLC can be formed provided the deposition conditions allow for sidewards pressure to form from a substrate close beneath the tubes. Under optimal DLC formation energies of around 40-70 eV, the top two nanotube atom layers are fully destroyed by the plasma deposition, but layers below this can retain their structural integrity. V C 2015 AIP Publishing LLC.

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Section: Introductionmentioning

confidence: 99%

Conditions for forming composite carbon nanotube-diamond like carbon material that retain the good properties of both materials

Ren

Iyer

Koskinen

et al. 2015

Journal of Applied Physics

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“…In 1997 we reported for the fi rst time low-k DLC fi lms stable up to 400°C [25] and FDLC fi lms with k = 2.3 have been reported elsewhere [27].…”

Section: Properties Of Dlc-type Low-k Dielectrics Dlcmentioning

confidence: 87%

“…Low-k DLC fi lms have been prepared by RF PECVD in a parallel plate reactor, at pressures of 100-300 mTorr and RF powers of 25-100 W, corresponding to power densities of 0.08-0.31 W/cm 2 , as described in detail elsewhere [25,26]. The RF plasma was sustained with a RF power supply at a frequency of 13.56 MHz.…”

Section: Preparationmentioning

confidence: 99%

“…FDLC fi lms, generally characterized by lower dielectric constants then DLC, have been deposited from fl uorocarbons, mixtures of fl uorocarbons with hydrogen, or mixtures of fl uorocarbons with hydrocarbons, using parallel plate RF PECVD reactors [26,27] or highdensity plasma reactors [28,29]. Contrary to DLC, low-k FDLC fi lms can be deposited at temperatures up to 400°C and on either electrode of the parallel plate reactor.…”

Section: Preparationmentioning

confidence: 99%

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Low and Ultralow Dielectric Constant Films Prepared by Plasma‐enhanced Chemical Vapor Deposition

Grill

2007

Dielectric Films for Advanced Microelectronics

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“…Although many low-k materials in the range of 2.0-4.0 [1][2][3][4][5] have been studied, integration problems and issues like moisture adsorption brought numerous reliability concerns. Methylsilsesquixane ͑MSQ͒ is an attractive candidate for replacement of SiO 2 in future generation ICs because of its inherent low-k ͑2.8͒ and good thermal stability.…”

mentioning

confidence: 99%

Electric field and temperature-induced removal of moisture in nanoporous organosilicate films

Biswas

Lubguban

Gangopadhyay

2004

Applied Physics Letters

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The effects of bias-temperature-stress ͑BTS͒ or simply temperature-stress ͑TS͒ on nanoporous low-k methylsilsesquioxane films are studied. Initially, the as-given and O 2 ashed/etched films exhibit physical adsorption of moisture as revealed from the electrical behavior of the samples after 15 days. The temperature stressing at 170°C volatilized the adsorbed water but is unable to remove chemisorb and hydrophillic Si-OH groups. As a result, the TS films remain susceptible to moisture. BTS at 170°C also removes adsorbed water. More important, the surfaces under the metal-insulator structure were dehydroxylated by breaking the chemisorb Si-OH group facilitating the formation of siloxane bonds that prevents adsorption of moisture even after 60 days. © 2004 American Institute of Physics. ͓DOI: 10.1063/1.1757019͔As device dimensions shrink, the struggle to find ultralow dielectric constant ͑k͒ materials for future generation integrated circuits ͑ICs͒ continues unabated. Although many low-k materials in the range of 2.0-4.0 1-5 have been studied, integration problems and issues like moisture adsorption brought numerous reliability concerns. Methylsilsesquixane ͑MSQ͒ is an attractive candidate for replacement of SiO 2 in future generation ICs because of its inherent low-k ͑2.8͒ and good thermal stability. The introduction of nanopores to MSQ provides extendibility of dielectric constant to values lower than 2.0. However, the dielectric properties of this nanoporous material are seriously degraded during photoresist removal-an important microelectronic fabrication step that involves O 2 ashing/etching. 6,7 This process also removes the hydrophobic CH x groups from exposed surfaces ͑pore surface as well͒ of the film and allowing the formation of silanol ͑Si-OH͒ groups. As a result, the hydrophillic Si-OH enhances physical adsorption of moisture upon air exposure and increases the dielectric constant. This causes device reliability problems. Device instabilities could occur causing an increase in leakage currents that may lead to breakdown of the dielectric film.Current work focuses on studying the effects of biastemperature-stress ͑BTS͒ or temperature-stress ͑TS͒ of nanoporous MSQ. BTS has been a very effective method to detect device instabilities like the presence of mobile ions or diffusion of metal ions in the dielectric. The time-dependent moisture adsorption and thermal stability of as-given and O 2 ashed/etched MSQ films are also investigated. This study will attempt to explain the susceptibility of MSQ films to moisture after BTS or TS.The nanoporous MSQ films studied are courtesy of Tokyo Electron America ͑TEL͒. The as-given and O 2 ashed/ etched MSQ for electrical measurements have thicknesses of 390 and 280 nm, respectively. To fabricate metalinsulator-semiconductor ͑MIS͒ devices, metal dots of titanium with an area 4.9ϫ10 Ϫ4 cm 2 were sputter-deposited. The capacitance-voltage (C -V) measurements were carried out on HP4284 LCR meter while current-voltage measurements were carried out on Keithly 2400 Sourcemet...

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Diamondlike Carbon Materials as Low-k Dielectrics for Multilevel Interconnects in Ulsi

Cited by 42 publications

References 7 publications

Conditions for forming composite carbon nanotube-diamond like carbon material that retain the good properties of both materials

Conditions for forming composite carbon nanotube-diamond like carbon material that retain the good properties of both materials

Low and Ultralow Dielectric Constant Films Prepared by Plasma‐enhanced Chemical Vapor Deposition

Electric field and temperature-induced removal of moisture in nanoporous organosilicate films

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